Multi-grip blind rivet

ABSTRACT

A multi-grip blind rivet  74  includes a rivet body  82 , adapted to receive a portion of a mandrel  76 . A plurality of indentations  88  are formed in an outer surface  86  of the rivet body  82  in each of three axially spaced transaxial planes. Each indentation  88  is formed with a work hardened base surface  90  having a convex portion, which is formed with axially spaced first and second transaxial edges  106  and  108  having nonlinear portions. Adjacent indentations  88  are separated by ribs  89 . A flared intermediate surface  122  extends between the base surface  90  and the outer surface  86 . The rivet  74  is assembled within aligned holes  128  and  130  of workpieces  124  and  126 , respectively, where, upon setting of the rivet, the indentations  88  collapse and the outer surface  86  bulges against walls of the holes to retain the workpieces together.

This application is a continuation-in-part of applicant's co-pendingapplication U.S. application Ser. No. 10/153,761, filed May 22, 2002,and titled MULTI-GRIP BLIND RIVET, which is pending. The disclosure ofapplicant's above-noted co-pending application is incorporated herein byreference thereto.

BACKGROUND OF THE INVENTION

This invention relates to a multi-grip blind rivet, and particularlyrelates to a multi-grip blind rivet having one or more radialindentations formed in one or more transaxial planes of a rivet body ofthe rivet.

Typically, multi-grip blind rivets include a mandrel, or stem, formedwith a head at one axial end thereof, and a rivet body, formed as asleeve or shank having a passage therethrough and a flange at one axialend thereof. A mandrel-body assembly is formed by inserting a non-headend of the mandrel into the passage at a non-flange end of the rivetbody and through the passage. With this assembly, the head of themandrel is eventually resting against the non-flange end of the rivetbody and the non-head end of the mandrel is extending outward from theflange end of the body. The assembly is then processed through a formingoperation where a groove is, or plural indentations are, formed in theouter periphery of the rivet body in a given transaxial plane. Aplurality of grooves could be formed in the outer periphery of the rivetbody, in spaced transaxial planes, along the axial length of the body inlieu of the indentations.

In known multi-grip rivets of the type described above, the grooves arecontinuous, and concave with respect to outer surface of the shank, witha concave work hardened surface formed at the base of the groove. Withrespect to the known multi-grip rivets which are formed withindentations, each such indentation, and the base thereof, could beconcave with a concave work hardened base. Or, the indentations could beformed with flared upper and lower walls extending from a flat workhardened surface, which is in the form of a secant to the circumferenceof the shank of the rivet body.

Subsequent to the formation of the grooves in the rivet body, themandrel-body assembly is placed within aligned openings of two or moreworkpieces to be secured together by the rivet. The diameter of thealigned openings is greater than the diameter of the external surface ofthe shank of the rivet body. In this position, an outer surface of oneof the workpieces is in interfacing engagement with an underside surfaceof the flange of the rivet body. Thereafter, while supporting the flangeof the rivet by the nosepiece of the setting tool, the setting of therivet begins by applying a pulling load, in an axial direction away fromthe flange, on the portion of the mandrel which extends outward from theshank of the rivet body. The pulling load on the mandrel is transferredto the rivet body shank under a compressive load.

Continued application of the pulling load results initially in theoutward radial bulging of the rivet body located axially between thespaced planar grooves followed by near axial closing of each of thegrooves and a corresponding axial shortening of the rivet body. As theoutwardly bulging section of the rivet body contacts the outer surfaceof the workpiece, and with the shortening of the axial length of therivet body, the workpiece parts are clamped together.

Eventually, the multi-grip blind rivet has been set whereby the bulgingsections of the rivet body are in firm, distorting engagement with theinner walls of the aligned holes of the workpieces, which creates agripping action between the bulging sections and the inner walls toretain the workpieces together.

The setting performance of the above-described multi-grip blind rivet,commonly configured either with grooves or swaged indentations along therivet body, does not perform well where the materials of the workpiecesare soft and/or friable, especially where the holes are oversize andthere are extremes of grip thickness.

A common form of multi-grip blind rivet, as illustrated and described inU.S. Pat. Nos. 4,958,971 and 6,004,086, has circumferential grooves,usually hemispherical in shape, spaced at intervals along the axiallength of the shank of the rivet body. The grooves are concave withrespect to the outer surface of the shank of the rivet body. As thistype of blind rivet is being set, the plain cylindrical rivet bodyportions between the grooves expand radially to form a characteristic“cottage loaf” setting and the grooves collapse in an axial directiongiving the capability for wider workpiece thicknesses.

As further illustrated and described in U.S. Pat. No. 6,254,324, one ormore reinforcing ribs may be formed within the circumferential concavegroove, or between circumferential-groove-like indentations, and extendradially from the base of the groove to the outer periphery of the shankof the rivet body.

The control of the depth of the grooves is critical to accommodate theextreme conditions mentioned. For example, if the groove is too deep,cracking of the base of the groove will occur upon setting of the rivet.If the groove is too shallow, there will not be sufficient resistance toprevent the mandrel head from pulling into, or even through, the rivetbody.

With respect to the above-noted U.S. patents, a work hardened area maybe formed at the base, or bottom, of the groove and will contribute tothe development of a resistance to the pulling of the mandrel head intothe rivet body. Also, the load being exerted by the mandrel head istransposed to the rivet body and to the groove profile. This loadincreases under the action of the setting tool causing the rivet body toexpand radially between the grooves as the body shortens. The settingprocess reaches a point where groove closes or collapse, therebyindicating the completion of the setting of the rivet.

Small differences in the groove depth of the grooves, as illustrated anddescribed in the above-noted U.S. patents, can give significantdifferences in the collapse load. This condition, together with normalmanufacturing variations in mandrel crimp breakload, could lead toeither premature rivet body failure or the pulling of the mandrel headinto the rivet body.

In another type of multi-grip rivet, as illustrated and described inU.S. Pat. No. 5,496,140, indentations are formed at predetermineddistances along the shank of the rivet body, with flared upper and lowerwalls extending outward from a flat work hardened base, which is in theform of a secant to the circumference of the shank. During the settingoperation of this type of rivet, the indented portions retain theirintegrity and allow the intermediate portions between the indentationsto collapse.

With respect to the rivet illustrated and described in U.S. Pat. No.5,496,140, after the mandrel-body assembly has been formed as describedabove, the rivet body is indented with a series of flat-bottomindentations, such as four equispaced identical indentations in a commontransaxial plane around the rivet body. The formation of theindentations provide four thickened portions with work hardened zonestherebetween. This structure avoids fully circumferential work hardeningand the subsequent risk of rivet body cracking during the application ofthe mandrel setting load.

As the rivet-setting load is being applied in the setting of the rivetof U.S. Pat. No. 5,495,140, the rivet section, which includes the fourthickened portions and the indentations, is supporting the setting load.Again, there is a point in the setting profile where the setting loadovercomes the resistance of the work hardened zones and the indentationscollapse to complete the setting of the rivet. With this type of rivet,body rupturing is avoided, but only small variations in indentationdepth and mandrel crimp break load could result in an incomplete settingor the mandrel head being pulled through the rivet body.

When setting rivets of the types described above, there are two basicconcerns which must be addressed:

-   -   a. During setting in softer workpiece materials, the grooves or        indentations are required to be deeper than normal to prevent        the mandrel head from pulling through the rivet body. However,        this structure can cause fracture of the rivet body, due partly        to the thinness of the material of the body and partly to the        degree of material work hardening. If the grooves or        indentations are not at an optimum depth, the mandrel can be        pulled into the rivet body; and    -   b. If the grooves or indentations are less than optimum during        the setting operation, the mandrel head can be pulled through        the rivet body due to insufficient resistance being provided by        the rivet body, and little or no resistance being provided by        the soft workpiece materials. In extreme cases, the result is        that the portion of the mandrel shaft extending from the mandrel        head can protrude beyond the flange, thereby creating a        potentially hazardous condition. Such a condition could cause        excessive radial expansion of the rivet body resulting in        splitting of the workpiece material as the radial expansion        takes place within the hole of the workpiece.

SUMMARY OF THE INVENTION

Therefore, it is an object of this invention to provide a multi-gripblind rivet which will provide excellent performance when used with avariety of workpiece materials, and including workpieces having widevariations of plate thickness and oversize holes and/or slots.

Another object of this invention is to provide a multi-grip blind rivetthat provides a relatively wider band of resistance to the setting load.

A further object of this invention is to provide a multi-grip blindrivet which is relatively inexpensive to manufacture.

With these and other objects in mind, this invention contemplates amulti-grip blind rivet which includes a mandrel and a hollow cylindricalbody having an outer surface and formed about an axis thereof andadapted to receive at least a portion of the mandrel therethrough. Aplurality of indentations are formed in the outer surface of thecylindrical body, with at least one indentation of the plurality ofindentations formed with a base surface having a convex portion.

In addition, this invention contemplates a multi-grip blind rivet whichincludes a mandrel and a hollow cylindrical body having an outer surfaceand formed about an axis thereof and adapted to receive at least aportion of the mandrel therethrough. A plurality of indentations areformed in the outer surface of the cylindrical body, with eachindentation formed with a base surface having a first transaxial edge,and a second transaxial edge spaced axially from the first transaxialedge. The first transaxial edge is nonlinear such that axial distancesbetween a plurality of pairs of axially spaced points of the first andsecond transaxial edges varies between the opposite ends of the firsttransaxial edge.

Further, this invention contemplates a multi-grip blind rivet whichincludes a mandrel and a hollow cylindrical body having an outer surfaceand formed about an axis thereof and adapted to receive at least aportion of the mandrel therethrough. A plurality of indentations areformed in the outer surface of the hollow cylindrical body, with atleast one indentation of the plurality of indentations formed with abase surface having an endless outboard edge around the base surface.The at least one indentation is formed with an intermediate surfacewhich extends between, and is contiguous with, the outer surface of thehollow cylindrical body and the entirety of the endless outboard edge ofthe base surface.

Additionally, this invention contemplates a plurality of ribs formed inthe transaxial plane with each rib separating an adjacent pair of theplurality of indentations.

Other objects, features and advantages of the present invention willbecome more fully apparent from the following detailed description ofthe preferred embodiment, the appended claims and the accompanyingdrawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings:

FIG. 1 is a side view showing a portion of a first prior art multi-gripblind rivet;

FIG. 2 is a side view of the rivet of FIG. 1 with arrows showing thedirections of setting loads resulting from a pulling or setting loadapplied to a mandrel of the first prior art rivet;

FIG. 3 is a sectional view taken along line 3-3 of FIG. 1 showingcertain structural features of the first prior art rivet;

FIG. 4 is a side view showing a portion of a second prior art multi-gripblind rivet;

FIG. 5 is a side view of the rivet of FIG. 4 with arrows showing thedirections of setting loads resulting from a pull load applied to amandrel of the second prior art rivet;

FIG. 6 is a sectional view taken along line 6-6 of FIG. 1 showingcertain structural features of the second prior art rivet;

FIG. 7 is a partial-sectional side view showing a multi-grip blindrivet, including a mandrel in assembly with a rivet body havingindentations formed in an outer surface thereof, in accordance withcertain principles of the invention;

FIG. 8 is a partial side view showing the indentations formed in therivet body of FIG. 7 in accordance with certain principles of theinvention;

FIG. 9 is a side view of the rivet of FIG. 7 with arrows showing thedirections of setting loads resulting from a pull load applied to themandrel in accordance with certain principles of the invention;

FIG. 10 is a sectional view taken along line 10-10 of FIG. 8 showingstructural features of portions of the indentations of the rivet body ofFIG. 7 in accordance with certain principles of the invention;

FIG. 11 is a side view showing the multi-grip blind rivet of FIG. 7 inassembly with two workpieces, of generally equal thickness, which are tobe retained together by the eventual setting of the rivet in accordancewith certain principles of the invention;

FIG. 12 is a side view showing early-stage radial bulging of the rivetbody of FIG. 11 and an early phase of the collapsing or closing of theindentations of FIG. 7 in accordance with certain principles of theinvention, with the workpieces of FIG. 11 not shown for the purpose ofclarity;

FIG. 13 is a side view showing later-stage radial bulging of the rivetbody of FIG. 11 and a later phase of the continuation of the collapsingof the indentations of FIG. 7 formed in the body in accordance withcertain principles of the invention, with the workpieces not shown forthe purpose of clarity;

FIG. 14 is a side view showing a set rivet after final-stage radialbulging of the rivet body of FIG. 11 and completion of the collapsing ofthe indentations of FIG. 7 formed in the body in accordance with certainprinciples of the invention, with the workpieces of FIG. 11 being shown;

FIG. 15 is a side view showing a set rivet in assembly with the twoworkpieces of FIG. 11, and a third workpiece of greater thickness, toretain the three workpieces together, in accordance with certainprinciples of the invention;

FIG. 16 is a side view showing a set rivet in assembly with a firstworkpiece of a prescribed thickness, and a second workpiece of athickness greater than the prescribed thickness, to retain the twoworkpieces together, in accordance with certain principles of theinvention, and

FIG. 17 is a perspective view showing a portion of the rivet body ofFIG. 7, with the indentations formed therein in accordance with certainprinciples of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to FIGS. 1, 2 and 3, a prior art multi-grip blind rivet 30includes a mandrel 32 formed with a stem 34 and a pulling head 36, and arivet body 38 having an axial passage 40. An outer surface 42 of therivet body 38 is formed, in a transaxial plane, with a plurality ofindentations 44, each of which is concave, as viewed from the exteriorof the rivet body, and generally hemispherical in shape. A plurality ofribs 46 are formed in the outer surface 42 of the rivet body 38, formedas a result of the indentations 44, with each rib separating adjacentindentations. An inward-most portion 48 of each indentation 44 is workhardened as represented by cross hatching in FIG. 1. A multi-grip blindrivet of this type is illustrated and described in U.S. Pat. No.6,254,324.

Referring to FIGS. 4, 5 and 6, another prior art multi-grip blind rivet50 includes a mandrel 52 formed with a stem 54 and a pulling head 56,and a rivet body 58 having an axial passage 60. An outer surface 62 ofthe rivet body 58 is formed, in a transaxial plane, with a plurality ofindentations 64, each of which is formed with a flat inner surface 66,as viewed from the exterior of the rivet body, and a pair of flaredtransition surfaces 68 and 70 spatially located on axially oppositesides of the surface 66. Referring to FIG. 4, each of the flat innersurfaces 66 are work hardened as represented by the cross hatching and,referring to FIG. 6, form a secant to the circular configuration of theouter surface 62 of the rivet body 58. The indentations 64 arestructured such that a large portion 72 of the rivet body remainsbetween, and separates, adjacent indentations. A multi-grip blind rivetof this type is illustrated and described in U.S. Pat. No. 5,496,140.

In use of each of the rivets 30 and 50, workpieces (not shown) areassembled, in a conventional manner, where the unset rivet componentsrest on a flange (not shown), which is formed on an end of the rivetbody. Thereafter, a free end portion of the mandrel stem, which extendsfrom the flange end of the rivet body, is grasped and pulled away fromthe rivet body. As a result of the stem-pulling action, a rivet-settingload is applied through the mandrel head to the adjacent end of therivet body, as shown by an upper row of arrows in FIGS. 2 and 5. Also,load forces are exerted on axially opposite sides of the indentations,as shown in FIGS. 2 and 5, whereby the indentations begin to, andeventually, collapse and close. Also, the outer surface of the rivetbody bulges outward, or expands radially, to provide for securanceengagement between the rivet and the workpieces, thereby retaining theworkpieces together.

As noted above, multi-grip blind rivets of the type illustrated in FIGS.1 through 6 perform well when securing workpieces composed of relativelyhard materials. However, problems could be encountered when theworkpieces are composed of materials that are soft and/or friable,particularly when the holes of the workpieces are oversized and thereare extremes of grip thickness. Also, with the softer and/or friableworkpieces, there could be concern for the undesirable pulling of themandrel head through the rivet body during the application of thesetting load. Further, as noted above, possible problems could berelated to the depth of the indentations, such as when the depth of theindentation is too deep, or too shallow.

Referring now to FIGS. 7 and 15, in the preferred embodiment of theinvention, a multi-grip blind rivet 74 includes a mandrel 76 formed witha stem 78 and a pulling head 80 at one end of the stem. The pulling head80 is formed with an underside surface 102.

The rivet 74 further includes a rivet body, or a hollow cylindricalbody, having an axial passage 84 formed about an axis 85 (FIG. 8) of therivet body. The rivet body 82 is formed with an outer surface 86 at aprescribed radius about the axis 85. The rivet body 82 is also formedwith a flange 92, at a flange end thereof, which has a flat surface 94facing a sleeve-like portion of the rivet body and has a dome-likesurface 96 facing away from the sleeve-like portion. A breakneck 98 isformed in the stem 78 of the mandrel 76, near the flange 92, and isconsiderably spaced from the mandrel head 80. A flangeless end 100 isformed at an end of the rivet body 82, opposite the flange end thereof.

During assembly of the components of the rivet 74, the stem 78 of themandrel 76 is inserted into the passage 84 at the flangeless end 100 ofthe rivet body 82 until the underside surface 102 of the mandrel head 80engages the flangeless end. The axial length of the mandrel stem 78 issuch that a free end portion 103 of the stem extends outward from thepassage 84 at the flange end of the rivet body 82.

Thereafter, the outer surface 86 of the rivet body 82 is formed with afirst plurality of indentations 88 a, a second plurality of indentations88 b, and a third plurality of indentations 88 c, which are located inthree axially spaced first, second and third transaxial planes,respectively, as illustrated in FIG. 7. It is noted that, in thepreferred embodiment, the plurality of indentations 88 b in the secondtransaxial plane, which is the middle plane of the three planes, iscloser to the plurality of indentations 88 c in the third transaxialplane than to the plurality of indentations 88 a in the first transaxialplane.

The three transaxial planes define four segments 87 a, 87 b, 87 c and 87d of the rivet body 82 between opposite ends of the rivet body, as shownin FIGS. 7 and 11, which are also shown as deformed segments in FIGS.12, 13, 14 and 16. Of the four segments, the segments 87 a and 87 d areof the shortest axial length, which could be of equal, or unequal,lengths, without departing from the spirit and scope of the invention.The segment 87 b is of the longest axial length, and the segment 87 c isof an intermediate axial length, as compared to the shortest and thelongest axial lengths.

In the preferred embodiment, the rivet 74 is formed with the foursegments 87 a, 87 b, 87 c and 87 d. The rivet could be formed with twosegments, three segments, or more than four segments, without departingfrom the spirit and scope of the invention.

Hereinafter, the numeral “88” will be used to refer to the indentationsgenerally, and the numerals “88 a,” “88 b” and “88 c” will be used torefer to the specific indentations in the first, second and thirdtransaxial planes, respectively.

In the preferred embodiment, there are four indentations 88 in each ofthe first, second and third transaxial planes. As few as twoindentations 88, and as many as practical, for example, at least eightindentations 88, could be formed in any one or more of the first, secondand third transaxial planes without departing from the spirit and scopeof the invention.

In addition, a plurality of indentations could be formed in the outersurface 86 of the rivet body 82 in a single transaxial plane, instead ofin three transaxial planes of the preferred embodiment, with at leastone indentation of the plurality of indentations in the single planeconforming to the structure of the indentation 88, without departingfrom the spirit and scope of the invention.

The rivet body 82 is formed with a plurality of ribs 89 in the first,second and third transaxial planes, with each rib separating adjacentindentations 88 in a respective one of the three planes. Eachindentation 88 is formed with an inward-most base surface 90, which iswork hardened as represented by cross hatching in FIG. 8.

Referring to FIG. 8, the base surface 90 of each indentation 88 isformed with an endless outboard edge 104 around the base surface. Theendless outboard edge 104 includes a first transaxial edge 106 and asecond transaxial edge 108, which is spaced axially from the firsttransaxial edge. The endless outboard edge 104 further includes a firstside edge 110 and a second side edge 112, which are axially aligned andcircumferentially spaced from each other. The first side edge 110 andthe second side edge 112 are integrally joined with respective oppositeends of the first and second transaxial edges 106 and 108 to therebyform the endless outboard edge 104 of the base surface 90.

It is noted that the shape of the indentation 88, as viewed from theexterior of the rivet 74, is generally similar to the shape of a human“eye.”

The first transaxial edge 106 of the base surface 90 is nonlinearbetween opposite ends thereof, such that axial distances between aplurality of pairs of axially spaced points of the first and secondtransaxial edges 106 and 108, respectively, varies between opposite endsof the first transaxial edge. For example, assume that the firsttransaxial edge 106 is shaped as an arc, as shown in FIG. 8, whichextends in an axial direction away from the second transaxial edge 108,and that, for purposes of this example, the second transaxial edge 108is linear between opposite ends thereof. Then select a first pair ofspaced points on the first and second transaxial edges 106 and 108,respectively, with the pair of points being axially aligned, andadjacent the second side edge 112. In this instance, the distancebetween the first pair of points is slightly greater than the length ofthe second side edge 112, due to the slight rise of the arc of thenonlinear first transaxial edge 106 at that point.

Then select a second pair of axially aligned points on the first andsecond transaxial edges 106 and 108, respectively, at a location equallycircumferentially spaced, for example, from the first and second sideedges 110 and 112, respectively. At this location, the arc of thenonlinear first transaxial edge 106 is at its farthest axial distancefrom the second transaxial edge 108, which represents the distancebetween the second pair of points. Comparatively, the distance betweenthe second pair of points is greater than the distance between the firstpair of points. This example represents the manner in which therespective axial distances between a plurality of axially spaced pointson the first and second transaxial edges 106 and 108, respectively,varies between opposite ends of the first transaxial edge.

It is noted that, in the preferred embodiment, both the first and secondtransaxial edges 106 and 108, respectively, are each nonlinear betweenopposite ends thereof. However, either, but not both, the firsttransaxial edge 106 or the second transaxial edge 108 could be linear,as in the example above, and the other edge be nonlinear withoutdeparting from the spirit and scope of the invention. Further, eitherthe first transaxial edge 106 or the second transaxial edge 108, orboth, could be formed with a nonlinear portion, rather than the entiretyof the edges being nonlinear, without departing from the spirit andscope of the invention.

In addition, the second transaxial edge 108 can be formed in the shapeof an arc, as illustrated in FIG. 8, extending in an axial directionaway from the first transaxial edge 106. In the preferred embodiment,the arcs of the first and second transaxial edges 106 and 108,respectively, of each base surface 90 are of the same shape and are inan orientation in which the first and second transaxial edges areconcave toward each other.

Referring to FIG. 8, the inward extent of the base surface 90 is shownas vertical lines within two indentations 88 on radially opposite sidesof the rivet 74. Referring to FIG. 10, the base surface 90 of eachindentation 88 extends outward and is formed with a convex portionbetween the first and second side edges 110 and 112, respectively, asviewed from the exterior of the rivet body 82. Further, as shown in FIG.10, the base surface 90 of each indentation 88 forms an arc surfacefacing in a direction away from the axis 85 (FIG. 8) of the rivet body82, and is formed at a radius about the axis of the rivet body which isless than the prescribed radius of the outer surface 86 of the rivetbody.

Consequently, the arc surfaces, formed by the base surfaces 90 in anyone of the first, second or third transaxial planes, are each located onspaced portions of an imaginary circle which is concentric with, andwithin, a circle which is coincidental with the circumference of theouter surface 86 of the rivet body 82.

Referring again to FIG. 8, each of the indentations 88 is formed with afirst border surface 114, which is contiguous with the first transaxialedge 106 of the base surface 90, and which flares away from the basesurface, toward the flangeless end 100 of the rivet body 82 and towardthe outer surface 86 of the body. Each of the indentations 88 is alsoformed with a second border surface 116, which is contiguous with thesecond transaxial edge 108 of the base surface 90, and which flares awayfrom the base surface toward the flange 92 (FIG. 7) of the rivet body 82and toward the outer surface 86 of the body.

The preferred embodiment of the rivet 74 is formed with the flared firstborder surface 114 and the flared second border surface 116, which arecontiguous with first transaxial edge 106 and the second transaxial edge108, respectively, to provide a transition between the base surface 90and the outer surface 86 of the rivet body 82. The transition surfaces,between the base surface and the outer surface 86, need not be flared,but could be, for example, surfaces which are at right angles to thebase surface 90 without departing from the spirit and scope of theinvention.

Referring to FIGS. 8 and 10, each of the indentations 88 is furtherformed with a third border surface 118, which is contiguous with thefirst side edge 110 of the base surface 90, and which flares away fromthe base surface in a circumferential direction and toward the outersurface 86 of the rivet body 82. Each of the indentations 88 is furtherformed with a fourth border surface 120, which is contiguous with thesecond side edge 112 of the base surface 90, and which flares away fromthe base surface in a circumferential direction and toward the outersurface 86 of the rivet body 82.

The first, second, third and fourth border surfaces 114, 116, 118 and120, respectively, are in the form of a plurality of differentlyoriented surfaces which are integrally and continuously joined about theendless outboard edge 104 of the base surface 90 to form an intermediatesurface 122. The intermediate surface 122 is flared outward in differentdirections away from the endless outboard edge 104 of the base surface90, and extends between, and is contiguous with, the outer surface 86 ofthe rivet body 82 and the endless outboard edge.

Referring to FIG. 11, a first workpiece 124 and a second workpiece 126are to be retained together by a set rivet. the workpieces 124 and 126are generally of equal thickness, and are formed with respectiveoversize holes 128 and 130. The diameter of the holes 128 and 130 islarger than the diameter of the outer surface 86 of the rivet body 82,and are thereby oversize in comparison with the rivet body. Initially,the workpieces 124 and 126 are assembled with the rivet 74 as shown inFIG. 11. The free end 103 of the mandrel stem 78 is grasped and pulledaway from the flange 92 so that pull or setting loads are developed inthe direction of the arrows shown in FIG. 9.

The workpieces 124 and 126 are not shown in FIGS. 12 and 13 in orderthat the bulging of the segments 87 a, 87 b, 87 c and 87 d may bevisualized. As shown in FIG. 12, with the application of the settingload, the indentations 88 begin to collapse, and the segments 87 a, 87b, 87 c and 87 d of the rivet body 82 begin to bulge radially outward.In this mode, the segment 87 d is bulging toward engagement with thewalls of the holes 124 and 126 (FIG. 11), and the segments 87 a, 87 band 87 c are also bulging.

Referring to FIG. 13, upon continued pulling of the free end 103 of themandrel stem 78, the indentations 88 are nearly closed, and the segments87 a, 87 b, 87 c and 87 d continue to bulge radially outward. Also, themandrel head 80 is being pulled into the segment 87 a at the flangelessend 100 (FIG. 7) of the rivet body 82.

Eventually, as shown in FIG. 14, the rivet 74 is set whereby theindentations 88 are completely collapsed and closed, and the segments 87a, 87 b, 87 c and 87 d of the rivet body 82 have reached their maximumbulge. The segment 87 d has expanded radially outward to fully engagethe walls of the openings 128 and 130 of the workpieces 124 and 126,respectively, to facilitate retaining the workpieces together. Also, thesegment 87 c has expanded radially outward to overlap a portion of theouter surface of the workpiece 124, adjacent the opening 128 thereof, tocapture the workpieces 124 and 126 between the flange 92 and the segment87 c. In this manner, the workpieces 124 and 126 are retained together.

Additionally, the mandrel head 80 has been pulled farther into thesegment 87 a of the rivet body 82, with the segment having portions 134which wrap partially and slightly about a portion of the head to assistin retaining the mandrel 76 with the rivet body 82 after the rivet hasbeen set. Also, at this time, the portion of the mandrel stem 78, whichincludes the free end 103, separates at the breakneck 98 (FIG. 7) fromthe remaining portion of the breakneck, and is removed.

As shown in FIG. 15, another example of an assembly of workpiecesincludes a third workpiece 132, which has been assembled with the firstand second workpieces 124 and 126, as in the process step illustrated inFIG. 11. The third workpiece 132 is of a thickness which is greater thanthe thickness of either of the first and second workpieces. When therivet 74 is set, the expanded segment 87 d facilitates the retainingtogether of the first and second workpieces 124 and 126, as describedabove. The radially outward expansion of the segments 87 b and 87 c,which are located within an axial hole 133 of the third workpiece,facilitate the retention of the third workpiece with the first andsecond workpieces.

In addition, the mandrel head 80 has been pulled downward to the extentthat the segment 87 a expands radially outward, and overlaps a portionof an outward surface 135 of the third workpiece 132, which is adjacentthe hole 133, to capture the first, second and third workpieces 124, 126and 132 between the flange 92 and the expanded segment 87 a, to furtherfacilitate the retaining together of the three workpieces. Also, theportion 134 of the segment 87 a partially surrounds the head 80 toretain the mandrel 76 with the rivet body 82 after the rivet 74 has beenset.

As shown in FIG. 16, the workpiece 126, of a small thickness, and aworkpiece 136 of greater thickness, have been assembled with the unsetrivet 74, in accordance with the process step illustrated in FIG. 11.When the rivet 74 is set, the expanded segments 87 c and 87 d facilitatethe retaining together of the workpiece 126 and the workpiece 136. It isnoted that a portion of the segment 87 d expands into engagement withthe hole 130 of the workpiece 126, and the remaining portion of thesegment 87 d expands into engagement with a portion of a hole 138 of theworkpiece 136. The segment 87 c expands into engagement with theremaining portion of the hole 138. In addition, the mandrel head 80 hasbeen pulled downward to the extent that the segment 87 b expandsradially outward, and overlaps a portion of an outward surface of theworkpiece 136, which is adjacent the hole 138, to capture the workpieces126 and 136 between the flange 92 and the segment 87 b, to furtherfacilitate the retaining together of the workpieces. Also, the portion134 of the segment 87 a partially surrounds the head 80 to retain themandrel 76 with the rivet body 82 after the rivet 74 has been set.

The multi-grip blind rivet 74 provides excellent performance in a widevariation of workpiece thickness, oversize holes and/or slots in avariety of workpiece materials. This excellent performance is achievedby building the above-noted features into the rivet body 82 that give awider band of resistance to the setting load and, therefore, control theradial expansion, or bulging, of the rivet body 82. This will limit theextent to which the mandrel head 80 enters the rivet body 82.

As noted above, after assembly of the mandrel 76 with the rivet body 82,the plurality of indentations 88 are formed into the rivet body at theselected transaxial planes along the rivet body. It is the shape of theindentations 88 that give the multi-grip blind rivet 74 its ability fordelivering an improved control of collapse of the indentations, asestablished by the nonlinearity of the first and second transaxial edges106 and 108, respectively, to provide variable distances or widthstherebetween. In addition, the convex form of the base surface 90 of theindentations 88 provides an enhanced capability of the multi-grip blindrivet 74 for further control of the collapse of the indentations.

The depth of the variable distances, or width, between the first andsecond tranaxial edges 106 and 108, respectively, of the indentations 88can be more accurately controlled due to its relatively greater area ofcontact of the tooling. This will lead to a better and more predictableproduct performance. Additionally, since the mandrel breakneck 98 isremote from the mandrel head 80, a relatively greater stability duringthe setting of the rivet 74, and an improved resistance to shear aftersetting, can be obtained.

The segments 87 a, 87 b, 87 c and 87 d of the rivet body 82 bulge, orexpand, sequentially as the rivet body shortens under the action of thesetting tool. The work hardened base surface 90 in the indentations 88control the rate of collapse within the profile of the indentations.

The base surface 90 of the indentations 88, as well as the variabledistance, or width, follow the diametric shape of the rivet body 82, butare interrupted to form the four ribs 89. The material of theindentations 88 has a greater hardness compared with the material whichforms the ribs 89 between the indentations. The ribs 89 add resistanceto the collapse of the indentations 88.

The shape of the indentations 88 is not linear, as described above, andvaries in axial distance, or width, to provide an “eye” shaped profileas shown in FIG. 8. The arrangement of this shape provides greatersetting stability over a band of setting loads due to the variabledistance, or width, of the indentation 88. Thus, the variable geometryof the “eye” shape of the indentations 88 provides accrued benefits inthe form of a much better control and stable collapse of theindentations, and an indentation collapse that is progressive over abroad spread of setting load.

The attainment of better control of the setting of the rivet 74 is dueto the broad, work hardened area which will accommodate a greatervariation in the depth of the indentation 88 and in the break load ofthe mandrel breakneck 89. At the same time, since the variable distance,or width, portions may be progressively different in their maximumwidth, this will insure that the rivet body 82 will bulge progressivelyfrom the end of the rivet.

In general, the above-identified embodiments are not to be construed aslimiting the breadth of the present invention. Modifications, and otheralternative constructions, will be apparent which are within the spiritand scope of the invention as defined in the appended claims.

1.-29. (canceled)
 30. A multi-grip blind rivet comprising: a mandrelhaving a stem and a pulling head at one end of the stem; a hollowcylindrical body having an outer surface and formed about an axisthereof and adapted to receive the stem of the mandrel therethrough; anda plurality of indentations formed in the outer surface of thecylindrical body, at least one of the plurality of indentations formedwith a base surface having a first arcuate transaxial edge extendingalong a length thereof and concavely facing a second substantiallylinear transaxial edge spaced axially from the first arcuate transaxialedge.
 31. The multi-grip blind rivet of claim 30 wherein the at leastone indentation is positioned at an end of the hollow cylindrical bodyadjacent the pulling head and wherein the second linear transaxial edgeis positioned closer to the end than the first arcuate transaxial edge.